The impact of 3D fields on tearing mode stability of H-modes

New processes have been discovered in the interaction of 3D fields with tearing mode stability at low torque and modest β on DIII-D and NSTX. These are thought to arise from the plasma response at the tearing resonant surface, which theoretically is expected to depend strongly on plasma rotation and...

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Published in:Nuclear fusion 2011-07, Vol.51 (7), p.073016
Main Authors: Buttery, R.J, Gerhardt, S, La Haye, R.J, Liu, Y.Q, Reimerdes, H, Sabbagh, S, Chu, M.S, Osborne, T.H, Park, J.-K, Pinsker, R.I, Strait, E.J, Yu, J.H
Format: Article
Language:English
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Summary:New processes have been discovered in the interaction of 3D fields with tearing mode stability at low torque and modest β on DIII-D and NSTX. These are thought to arise from the plasma response at the tearing resonant surface, which theoretically is expected to depend strongly on plasma rotation and underlying intrinsic tearing stability. This leads to sensitivities additional to those previously identified at low density where the plasma rotation is more readily stopped, or at high β N where ideal MHD responses amplify the fields (where β N is the plasma β divided by the ratio of plasma current to minor radius multiplied by toroidal field). It is found that the threshold size for 3D fields to induce modes tends to zero as the natural tearing β N limit is approached. 3D field sensitivity is further enhanced at low rotation, with magnetic probing detecting an increased response to applied fields in such regimes. Modelling with the MARS-F code confirms the interpretation with the usual plasma screening response breaking down in low rotation plasmas and a tearing response developing, opening the door to additional sensitivities to β and the current profile. Typical field thresholds to induce modes in torque-free β N ∼ 1.5 H-modes are well below those in ohmic plasmas or plasmas near the ideal β N limit. The strong interaction with the tearing mode β N limit is identified through rotation shear, which is decreased by the 3D field, leading to decreased tearing stability. Thus both locked and rotating mode field thresholds can be considered in terms of a torque balance, with sufficient braking leading to destabilization of a mode. On this basis new measurements of the principal parameter scalings for error field threshold have been obtained in torque-free H-modes leading to new predictions for error field sensitivity in ITER. The scalings have similar exponents to ohmic plasmas, but with seven times lower threshold at the ITER baseline β N value of 1.8, and a linear dependence on proximity to the tearing mode β N limit (∼2.2 at zero torque). This reinforces the need to optimize error field correction strategies in ITER, and implement sources to drive plasma rotation.
ISSN:0029-5515
1741-4326
DOI:10.1088/0029-5515/51/7/073016